Evidence for multiple distinctly localized adenylyl cyclase isoforms in mammalian spermatozoa

In addition to a bicarbonate-regulated soluble adenylyl cyclase (sAC), mammalian spermatozoa, like somatic cells, appear to contain receptor/G protein-regulated AC activity that contributes to the modulation of specialized cell processes. This study provides evidence that agents, known to influence somatic membrane-associated AC (mAC) but apparently not germ cell sAC, can modulate cAMP production and functional state in mouse spermatozoa. Specifically, forskolin significantly enhanced cAMP production and capacitation, while inclusion of 2',5'-dideoxyadenosine significantly blocked these responses. Furthermore, GTPgammaS and NaF stimulated cAMP, but GDPbetaS and mastoparan had no apparent effect, consistent with recent evidence that G(s), but not G(i), contributes to AC/cAMP regulation in uncapacitated cells. In addition, intact mouse spermatozoa were screened for all known mAC isoforms by immunolocalization, using commercially available specific antibodies. The most abundant isoforms appeared to be AC2, AC3, and AC8, each with distinct distributions in the acrosomal and flagellar regions; AC1 and AC4 also appeared to be present, although less abundantly, in the midpiece and acrosomal cap regions, respectively. Intriguingly, however, Western blotting revealed that the major immunoreactive proteins in mouse sperm lysates were considerably smaller (approximately 50-60 kDa) than their somatic cell counterparts, suggesting that mature spermatozoa contain multiple mACs which may function in a shortened form. Of particular interest were AC3 and AC8, located in the same regions as, and hence possibly directly associated with, specific cell surface receptors and G proteins that are able to regulate the spermatozoon's acquisition and maintenance of fertilizing ability via changes in AC/cAMP.     

FPP modulates mammalian sperm function via TCP-11 and the adenylyl cyclase/cAMP pathway

Fertilization promoting peptide (FPP; pGlu-Glu-ProNH₂), which is found in seminal plasma, promotes capacitation but inhibits spontaneous acrosome loss in mammalian spermatozoa in vitro. Adenosine, known to modulate the adenylyl cyclase (AC)/cAMP pathway, elicits these same responses whereas FPP + adenosine produces an enhanced response, leading to the hypothesis that FPP and adenosine modulate the same signal transduction pathway but act via different receptors. TCP-11, the product of a t-complex gene, is the putative receptor for FPP: Fab fragments of anti-TCP-11 antibodies have the same effect as FPP on mouse spermatozoa and Gln-FPP, a competitive inhibitor of FPP, also competitively inhibits responses to the Fab fragments. In the present study, specific binding of ³H-FPP to sperm membranes was significantly inhibited by 200 nM Gln-FPP and anti-TCP-11 Fab fragments (1/25 dilution), thus confirming that FPP, Gln-FPP, and Fab fragments compete for the same binding site. In addition, spermatozoa treated with A23187 to induce the acrosome reaction bound significantly less ³H-FPP than untreated cells, suggesting that a large proportion of the FPP binding sites are associated with the acrosomal cap region; TCP-11 is located in this region. In other experiments, 100 nM FPP significantly stimulated cAMP production in mouse sperm membranes, permeabilized cells and intact cells. Furthermore, Gln-FPP inhibited production of cAMP in response to FPP but not to adenosine (10 μM) or its analogue NECA (100 nM), supporting the involvement of two different receptors. Finally, anti-TCP-11 Fab fragments (1/25 dilution) significantly stimulated cAMP production, whereas low Fab (1/200; nonstimulatory when used alone) plus adenosine (10 μM) significantly enhanced the stimulation of capacitation by adenosine. These results support the hypotheses that TCP-11 is the receptor for FPP and that FPP↔TCP-11 interactions modulate AC/cAMP. Mol. Reprod. Dev. 51:468–476, 1998. © 1998 Wiley-Liss, Inc.     

Calcitonin acts as a first messenger to regulate adenylyl cyclase/cAMP and mammalian sperm function

Calcitonin stimulates capacitation in uncapacitated mouse spermatozoa and then inhibits spontaneous acrosome loss in capacitated cells, responses similar to those elicited by fertilization promoting peptide (FPP), a peptide known to regulate the adenylyl cyclase/cAMP pathway. This study investigated the hypothesis that calcitonin also modulates this pathway. Calcitonin significantly stimulated cAMP production in uncapacitated spermatozoa and then inhibited it in capacitated cells; the magnitude of both stimulatory and inhibitory changes was similar to that obtained with FPP but the inhibitory responses to FPP preceded those of calcitonin. This possibly reflects the involvement of two different adenosine receptors in response to FPP compared with one calcitonin receptor. Calcitonin receptors were located on the acrosomal cap and the flagellum, the midpiece having a greater abundance than the principal piece. Although both calcitonin and adenosine receptors are found in the head and flagellum, there was no evidence for cross-talk between them. Chlortetracycline investigations to determine the minimum extracellular Ca(2+) requirement for responses to calcitonin revealed that calcitonin significantly stimulated capacitation in Ca(2+)-deficient medium but FPP did not. Calcitonin also significantly stimulated cAMP production under these conditions, and similarly preincubated suspensions, when diluted into +Ca(2+) medium, were significantly more fertile in vitro than untreated controls. These results indicate that calcitonin, like FPP, acts as a first messenger to regulate the production of cAMP and mammalian sperm function, but the differences in Ca(2+) requirements suggest that calcitonin and FPP may regulate different isoforms of adenylyl cyclase.     

Capacitation state-dependent changes in adenosine receptors and their regulation of adenylyl cyclase/cAMP

This study was designed to localize adenosine receptors and to provide evidence that specific receptors are active only in either uncapacitated or capacitated mouse spermatozoa, where they play a role in regulating cAMP production. Using specific antibodies, stimulatory A(2A) receptors were localized primarily on the acrosomal cap region and the flagellar principal piece. Interestingly, the staining was much more pronounced in uncapacitated than in capacitated spermatozoa, suggesting capacitation-dependent changes in epitope accessibility. A(1) receptors showed a very similar distribution, but the staining was markedly greater in capacitated than in uncapacitated cells. After addition of purified decapacitation factor (DF) to capacitated cells, strong staining for A(2A) was regained, suggesting reversibility in epitope accessibility. Chlortetracycline analysis revealed that an agonist specific for A(2A) receptors had no detectable effect on capacitated cells, but after DF-induced decapacitation, the agonist then stimulated capacitation. That agonist also significantly stimulated cAMP production in uncapacitated cells, had no effect on capacitated cells, but regained the ability to stimulate cAMP in the latter following DF treatment. In contrast, an A(1) agonist inhibited cAMP in capacitated cells. These results indicate that specific adenosine receptors function in a reversible manner in one or other capacitation state, resulting in regulation of cAMP.     

Investigation of the role of the carboxyl-terminal tails of the alpha and beta isoforms of the human thromboxane A(2) receptor (TP) in mediating receptor:effector coupling

We have investigated the functional coupling of alpha and beta isoforms of the human thromboxane A(2) receptor (TP) to Galpha(16) and Galpha(12) members of the G(q) and G(12) families of heterotrimeric G proteins in human embryonic kidney (HEK) 293 cell lines HEK.alpha10 or HEK.beta3, stably over-expressing TPalpha and TPbeta, respectively. Moreover, using HEK.TP(Delta328) cells which over-express a variant of TP truncated at the point of divergence of TPalpha and TPbeta, we investigated the requirement of the C-tail per se in mediating G protein coupling and effector activation. Both TPalpha and TPbeta couple similarly to Galpha(16) to affect increases in inositol 1,4,5-trisphosphate (IP(3)) and mobilisation of intracellular calcium ([Ca(2+)](i)) in response to the TP agonist U46619. Whilst both TP isoforms mediated [Ca(2+)](i) mobilisation in cells co-transfected with Galpha(12), neither receptor generated corresponding increases in IP(3), indicating that the Galpha(12)-mediated increases in [Ca(2+)](i) do not involve PLC activation. Verapamil, an inhibitor of voltage dependent Ca(2+) channels, reduced [Ca(2+)](i) mobilisation in TPalpha and TPbeta cells co-transfected with Galpha(12) to approximately 40% of that mobilised in its absence, whereas [8-(N,N-diethylamino)-octyl-3,4, 5-trimethoxybenzoate, hydrochloride] (TMB-8), an antagonist of intracellular Ca(2+) release, had no effect on [Ca(2+)](i) mobilisation by either receptor isoform co-transfected with Galpha(12). Despite the lack of differential coupling specificity by TPalpha and TPbeta, TP(Delta328) signalled more efficiently in the absence of a co-transfected G protein compared to the wild type receptors but, on the other hand, displayed an impaired ability to couple to co-transfected Galpha(11), Galpha(12) or Galpha(16) subunits. In studies investigating the role of the C-tail in influencing coupling to the effector adenylyl cyclase, similar to TPalpha but not TPbeta, TP(Delta328) coupled to Galpha(s), leading to increased adenosine 3',5'-cyclic monophosphate (cAMP), rather than to Galpha(i). Whereas TP(Delta328) signalled more efficiently in the absence of co-transfected G protein compared to the wild type TPalpha, co-transfection of Galpha(s) did not augment cAMP generation by TP(Delta328). Hence, from these studies involving the wild type TPalpha, TPbeta and TP(Delta328), we conclude that the C-tail sequences of TP are not a major determinant of G protein coupling specificity to Galpha(11) and Galpha(16) members of the G(q) family or to Galpha(12); it may play a role in determining G(s) versus G(i) coupling and may act as a determinant of coupling efficiency.     

Comparative distribution of short dystrophin superfamily products in various guinea pig spermatozoa domains

In this study, the presence and cellular distribution of dystrophin family products (i.e. Dp71d, Dp71f-like protein and dystrobrevin) was examined by indirect immunofluorescence and Western blotting in guinea pig spermatozoa. Two dystrophin-associated proteins, beta-dystroglycan and alpha-syntrophin, and nNOS a protein frequently associated with alpha-syntrophin, were determined. In spermatozoa lacking plasma membrane and acrosome, Dp71f-like protein was found in the postacrosomal perinuclear theca and also in the middle piece of the flagellum. In the flagellum, Dp71f-like protein is localized together with alpha-syntrophin and nNOS. Dp71d was present in the plasma membrane of the middle piece with beta-dystroglycan, alpha-syntrophin and nNOS. Dp71d was also present in plasma membrane of the post acrosomal region, but only with nNOS. Finally, dystrobrevin was located all along skeletal flagellum structures and in the subacrosomal hemisphere of the perinuclear theca. This distinct and complementary distribution in various domains of spermatozoa may reveal a specific function for each short dystrophin family product, in the stabilization of the domains where they are located.     

Molecular dissection of G protein preference using Gsalpha chimeras reveals novel ligand signaling of GPCRs

Although only 16 genes have been identified in mammals, several Galpha subunits can be simultaneously activated by G protein-coupled receptors (GPCRs) to modulate their complicated functions. Current GPCR assays are limited in the evaluation of selective Galpha activation, thus not allowing a comprehensive pathway screening. Because adenylyl cyclases are directly activated by G(s)alpha and the carboxyl termini of the various Galpha proteins determine their receptor coupling specificity, we proposed a set of chimeric G(s)alpha where the COOH-terminal five amino acids are replaced by those of other Galpha proteins and used these to dissect the potential Galpha linked to a given GPCR. Unlike G(q)alpha, G(12)alpha, and G(i)alpha outputs, compounding the signals from several Galpha members, the chimeric G(s)alpha proteins provide a superior molecular approach that reflects the previously uncharacterized pathways of GPCRs under the same cAMP platform. This is, to our knowledge, the first time allowing verification of the whole spectrum of Galpha coupling preference of adenosine A1 receptor, reported to couple to multiple G proteins and modulate many physiological processes. Furthermore, we were able to distinguish the uncharacterized pathways between the two neuromedin U receptors (NMURs), which distribute differently but are stimulated by a common agonist. In contrast to the G(q) signals mainly conducted by NMUR1, NMUR2 routed preferentially to the G(i) pathways. Dissecting the potential Galpha coupling to these GPCRs will promote an understanding of their physiological roles and benefit the pharmaceutical development of agonists/antagonists by exploiting the selective affinity toward a certain Galpha subclass.     

Gonadotropin-releasing hormone receptor initiates multiple signaling pathways by exclusively coupling to G(q/11) proteins

The agonist-bound gonadotropin-releasing hormone (GnRH) receptor engages several distinct signaling cascades, and it has recently been proposed that coupling of a single type of receptor to multiple G proteins (G(q), G(s), and G(i)) is responsible for this behavior. GnRH-dependent signaling was studied in gonadotropic alphaT3-1 cells endogenously expressing the murine receptor and in CHO-K1 (CHO#3) and COS-7 cells transfected with the human GnRH receptor cDNA. In all cell systems studied, GnRH-induced phospholipase C activation and Ca(2+) mobilization was pertussis toxin-insensitive, as was GnRH-mediated extracellular signal-regulated kinase activation. Whereas the G(i)-coupled m2 muscarinic receptor interacted with a chimeric G(s) protein (G(s)i5) containing the C-terminal five amino acids of Galpha(i2), the human GnRH receptor was unable to activate the G protein chimera. GnRH challenge of alphaT3-1, CHO#3 and of GnRH receptor-expressing COS-7 cells did not result in agonist-dependent cAMP formation. GnRH challenge of CHO#3 cells expressing a cAMP-responsive element-driven firefly luciferase did not result in increased reporter gene expression. However, coexpression of the human GnRH receptor and adenylyl cyclase I in COS-7 cells led to clearly discernible GnRH-dependent cAMP formation subsequent to GnRH-elicited rises in [Ca(2+)](i). In alphaT3-1 and CHO#3 cell membranes, addition of [alpha-(32)P]GTP azidoanilide resulted in GnRH receptor-dependent labeling of Galpha(q/11) but not of Galpha(i), Galpha(s) or Galpha(12/13) proteins. Thus, the murine and human GnRH receptors exclusively couple to G proteins of the G(q/11) family. Multiple GnRH-dependent signaling pathways are therefore initiated downstream of the receptor/G protein interface and are not indicative of a multiple G protein coupling potential of the GnRH receptor.     

RGS17/RGSZ2, a novel regulator of Gi/o, Gz, and Gq signaling

To identify novel regulators of Galpha(o), the most abundant G-protein in brain, we used yeast two-hybrid screening with constitutively active Galpha(o) as bait and identified a new regulator of G-protein signaling (RGS) protein, RGS17 (RGSZ2), as a novel human member of the RZ (or A) subfamily of RGS proteins. RGS17 contains an amino-terminal cysteine-rich motif and a carboxyl-terminal RGS domain with highest homology to hRGSZ1- and hRGS-Galpha-interacting protein. RGS17 RNA was strongly expressed as multiple species in cerebellum and other brain regions. The interactions between hRGS17 and active forms of Galpha(i1-3), Galpha(o), Galpha(z), or Galpha(q) but not Galpha(s) were detected by yeast two-hybrid assay, in vitro pull-down assay, and co-immunoprecipitation studies. Recombinant RGS17 acted as a GTPase-activating protein (GAP) on free Galpha(i2) and Galpha(o) under pre-steady-state conditions, and on M2-muscarinic receptor-activated Galpha(i1), Galpha(i2), Galpha(i3), Galpha(z), and Galpha(o) in steady-state GTPase assays in vitro. Unlike RGSZ1, which is highly selective for G(z), RGS17 exhibited limited selectivity for G(o) among G(i)/G(o) proteins. All RZ family members reduced dopamine-D2/Galpha(i)-mediated inhibition of cAMP formation and abolished thyrotropin-releasing hormone receptor/Galpha(q)-mediated calcium mobilization. RGS17 is a new RZ member that preferentially inhibits receptor signaling via G(i/o), G(z), and G(q) over G(s) to enhance cAMP-dependent signaling and inhibit calcium signaling. Differences observed between in vitro GAP assays and whole-cell signaling suggest additional determinants of the G-protein specificity of RGS GAP effects that could include receptors and effectors.     

Rab3A triggers the acrosome reaction in permeabilized human spermatozoa

The acrosome reaction is a regulated exocytotic process leading to a massive fusion between the outer acrosomal membrane and the cell membrane. In spite of the great amount of information available related to the acrosome reaction in several species, there is a remarkable paucity about the role of monomeric guanosine triphosphatases (GTPases) of the Rab family-well-established participants in exocytosis in other cell types-in the acrosome reaction. Western blot and immunofluorescence analysis indicate that Rab3A is present in human spermatozoa and localizes to the acrosomal region in the sperm head. One difficulty in studying the role of proteins in intact cells is the fact that they are unable to cross the cell membrane. Therefore, we established a working model of streptolysin O-permeabilized human spermatozoa. Permeabilized spermatozoa were able to respond in a regulated way to different stimuli, such as G protein activators and calcium. An acrosomal reaction was also triggered by a Rab3A peptide corresponding to the effector region. More important, recombinant Rab3A protein in the GTP-bound form caused acrosome exocytosis. The same protein loaded with GDP or Rab11 in the GTP-bound form was inactive. Also, recombinant GDI (GDP dissociation inhibitor)-a protein that releases Rab proteins from membrane-inhibited a GTPgammaS-stimulated acrosome reaction. Our results indicate that 1) permeabilized spermatozoa can be used to study the role of macromolecules in the acrosome reaction, 2) Rab3A is present in human spermatozoa, and 3) Rab3A or another Rab3 isoform is involved in the exocytosis of the acrosomal granule in human spermatozoa.     

The Multi-PDZ domain protein MUPP1 as a lipid raft-associated scaffolding protein controlling the acrosome reaction in mammalian spermatozoa

The success of acrosomal exocytosis, a complex process with a variety of interrelated steps, relies on the coordinated interaction of participating signaling molecules. Since scaffolding proteins are known to spatially organize sequential signaling pathways, we examined whether the Multi-PDZ domain protein MUPP1, recently identified in mammalian spermatozoa, is functionally active in controlling acrosomal secretion in mammalian sperm cells. To address this question, permeabilized mouse sperm were loaded with inhibitory antibodies against MUPP1 as well as with a photosensitive Ca(2+) chelator which allows a controlled release of acrosomal Ca(2+). The results revealed that MUPP1 controls initial tethering and docking of the acrosomal vesicle, whereas syntaxin 2, a t-SNARE protein also expressed in the acrosomal cap of mammalian spermatozoa, appears to take part in the final process of acrosomal fusion. Interestingly, using immunogold electron microscopy, it was found that MUPP1 is detectable in the region of the periacrosomal membrane. Furthermore, in isolated detergent-insoluble glycolipid-enriched membrane domains from epididymal spermatozoa, MUPP1 was found to show a striking association with the Triton X-100 insoluble membrane fraction, which did not change significantly upon sperm capacitation or partial chemical extraction of cholesterol. This evidence points to a role of MUPP1 as a membrane raft-associated molecular organizer, and suggests that mammalian spermatozoa may use a scaffolding protein and distinct membrane subdomains to spatially organize components involved in the process of acrosomal exocytosis.     

Gαs protein C‐terminal α‐helix at the interface: does the plasma membrane play a critical role in the Gαs protein functionality?

The heterotrimeric guanine nucleotide-binding regulatory proteins (G proteins, Galphabetagamma) mediate the signalling process of a large number of receptors, known as G protein-coupled receptors. The C-terminal domain of the heterotrimeric G protein alpha-subunit plays a key role in the selective activation of G proteins by their cognate receptors. The interaction of this domain can take place at the end of a cascade including several successive conformational modifications. Galpha(s)(350-394) is the 45-mer peptide corresponding to the C-terminal region of the Galpha(s) subunit. In the crystal structure of the Galpha(s) subunit it encompasses the alpha4/beta6 loop, the beta6 beta-sheet segment and the alpha5 helix region. Following a previous study based on the synthesis, biological activity and conformational analysis of shorter peptides belonging to the same Galpha(s) region, Galpha(s)(350-394) was synthesized and investigated. The present study outlines the central role played by the residues involved in the alpha4/beta6 loop and beta6/alpha5 loops in the stabilization of the C-terminal Galpha(s)alpha-helix. H(2)O/(2)H(2)O exchange experiments, and NMR diffusion experiments show interesting evidence concerning the interaction between the SDS micelles and the polypeptide. These data prompt intriguing speculations on the role of the intracellular environment/cellular membrane interface in the stabilization and functionality of the C-terminal Galpha(s) region.     

Relevance of glycosylation of human zona pellucida glycoproteins for their binding to capacitated human spermatozoa and subsequent induction of acrosomal exocytosis

To delineate the functional aspects of zona pellucida (ZP) glycoproteins during fertilization in human, in the present study, fluorochrome-conjugated Escherichia coli (E. coli)- and baculovirus-expressed recombinant human ZP glycoprotein-2 (ZP2), -3 (ZP3), and -4 (ZP4) were employed. In an immunofluorescence assay, capacitated human sperm exhibited binding of the baculovirus-expressed recombinant ZP3 as well as ZP4 to either acrosomal cap or equatorial region whereas acrosome-reacted sperm failed to show any binding to the acrosomal cap. Using double labeling experiments, simultaneous binding of ZP3 and ZP4 to the acrosomal cap was observed suggesting the possibility of different binding sites of these proteins on the sperm surface. No binding of ZP2 was observed to the capacitated sperm. However, acrosome-reacted sperm (20.00 +/- 1.93%) showed binding of ZP2 that was restricted to only equatorial region. Interestingly, E. coli-expressed recombinant human zona proteins also showed very similar binding profiles. Competitive inhibition studies with unlabeled recombinant human zona proteins revealed the specificity of the above binding characteristics. Binding characteristics have been further validated by an indirect immunofluorescence assay using native human heat solubilized isolated zona pellucida. Employing baculovirus-expressed recombinant ZP3 and ZP4 with reduced N-linked glycosylation and respective E. coli-expressed recombinant proteins, it was observed that glycosylation is required for induction of acrosomal exocytosis but its absence may not compromise on their binding ability. These studies have revealed the binding profile of individual human zona protein to spermatozoa and further strengthened the importance of glycosylation of zona proteins for acrosomal exocytosis in spermatozoa.     

Cryopreservation, actin localization and thermotropic phase transitions in ram spermatozoa

The effects of controlled stress, i.e. cooling, upon the distribution of actin in ram spermatozoa were examined to investigate the hypothesis that cytoskeletal proteins are involved in the maintenance of sperm plasma membrane integrity. The normal distribution of actin on the spermatozoon was initially determined. A monoclonal antibody (IgM) interacted exclusively with the post-acrosomal region and the principal piece of the flagellum. By the use of a polyclonal antibody, actin was detected on the acrosome (excluding the equatorial segment), the post-acrosomal region and the whole of the flagellum. The actin was present in its non-filamentous form. Spermatozoa fixed at 39 degrees C and then treated for the immunofluorescent detection of actin with the monoclonal antibody were mostly unstained (proportion stained = 4.4% (+/- 1.6; s.e.m.); n = 8 ejaculates). Provided spermatozoa were permeabilized by greater than 0.025% Triton X-100 before immunofluorescence, actin was localized in the postacrosomal region of all sperm heads, and to a minor extent on the principal piece of the flagellum. Use of the polyclonal antibody confirmed that the post-acrosomal antigen was unmasked by detergent treatment. Slow cooling, over 2-h periods to various temperatures between 5 and 15 degrees C, also induced an increase in the proportion of cells showing post-acrosomal actin immunoreactivity. Cooling through the temperature range 15 to 10 degrees C markedly increased the proportion of immunoreactive cells (mean +/- s.e.m.; 12 +/- 4.5% at 15 degrees C; 27 +/- 4.5% at 10 degrees C; n = 4 ejaculates). Further cooling to 5 degrees C failed to elicit increased staining. Ultrastructural examination of cooled spermatozoa confirmed that a subpopulation of spermatozoa exhibited post-acrosomal actin immunoreactivity after cooling. These results are compatible with the suggestion that actin fulfills a stabilizing function in spermatozoa.     

Mechanisms for reversible regulation between G13 and Rho exchange factors.

The heterotrimeric G proteins, G(12) and G(13), mediate signaling between G protein-coupled receptors and the monomeric GTPase, RhoA. One pathway for this modulation is direct stimulation by Galpha(13) of p115 RhoGEF, an exchange factor for RhoA. The GTPase activity of both Galpha(12) and Galpha(13) is increased by the N terminus of p115 Rho guanine nucleotide exchange factor (GEF). This region has weak homology to the RGS box sequence of the classic regulators of G protein signaling (RGS), which act as GTPase-activating proteins (GAP) for G(i) and G(q). Here, the RGS region of p115 RhoGEF is shown to be distinctly different in that sequences flanking the predicted "RGS box" region are required for both stable expression and GAP activity. Deletions in the N terminus of the protein eliminate GAP activity but retain substantial binding to Galpha(13) and activation of RhoA exchange activity by Galpha(13). In contrast, GTRAP48, a homolog of p115 RhoGEF, bound to Galpha(13) but was not stimulated by the alpha subunit and had very poor GAP activity. Besides binding to the N-terminal RGS region, Galpha(13) also bound to a truncated protein consisting only of the Dbl homology (DH) and pleckstrin homology (PH) domains. However, Galpha(13) did not stimulate the exchange activity of this truncated protein. A chimeric protein, which contained the RGS region of GTRAP48 in place of the endogenous N terminus of p115 RhoGEF, was activated by Galpha(13). These results suggest a mechanism for activation of the nucleotide exchange activity of p115 RhoGEF that involves direct and coordinate interaction of Galpha(13) to both its RGS and DH domains.     

Heterologous desensitization mediated by G protein-specific binding to caveolin

We examined the notion that sequestration of G protein subunits by binding to caveolin impedes G protein reassociation and leads to transient, G protein-specific desensitization of response in dispersed smooth muscle cells. Cholecystokinin octapeptide (CCK-8) and substance P (SP) were used to activate G(q/11), cyclopentyl adenosine (CPA) was used to activate G(i3), and acetylcholine (ACh) was used to activate both G(q/11) and G(i3) via m3 and m2 receptors, respectively. CCK-8 and SP increased only Galpha(q/11), and CPA increased only Galpha(i3) in caveolin immunoprecipitates; caveolin and other G proteins were not increased. ACh increased both Galpha(q/11) and Galpha(i3) in a time- and concentration-dependent fashion: only Galpha(q/11) was increased in the presence of an m2 antagonist, and only Galpha(i3) was increased in the presence of an m3 antagonist. To determine whether transient G protein binding to caveolin affected subsequent responses mediated by the same G protein, PLC-beta activity was measured in cells stimulated sequentially with two different agonists that activate either the same or a different G protein. After treatment of the cells with ACh and an m2 antagonist, the phospholipase C-beta (PLC-beta) response to CCK-8 and SP, but not CPA, was decreased; conversely, after treatment of the cells with ACh and an m3 antagonist, the PLC-beta response to CPA, but not CCK-8 or SP, was decreased. Similarly, after treatment with CCK-8 or SP, the PLC-beta response mediated by G(q/11) only was decreased, whereas after treatment with CPA, the PLC-beta response mediated by G(i3) only was decreased. A caveolin-binding Galpha(q/11) fragment blocked the binding of activated Galpha(q/11) but not Galpha(i3) to caveolin-3 and prevented desensitization of the PLC-beta response mediated only by other G(q/11)-coupled receptors. A caveolin-binding Galpha(i3) fragment had the reverse effect. Thus, transient binding of receptor-activated G protein subunits to caveolin impedes reassociation of the heterotrimeric species and leads to desensitization of response mediated by other receptors coupled to the same G protein.